VEHICLE ROOF SYSTEM

Abstract

In a vehicle roof system for closing and opening a roof opening (2a) formed in a fixed roof panel (2) of a vehicle with a moveable roof panel (4), an electric motor (24) mounted on a front edge of the roof opening actuates the moveable roof panel via a pair of push-pull cables (22). The drive section of at least one of the push-pull cable includes a bulging section bulging in a forward direction, and the elongated direction of the main body of the electric motor extends substantially in parallel with a sloping inboard side of the bulging section of the one push-pull cable. Therefore, the push-pull cable can be bulged forward without any restriction so that the push-pull cable can be laid out so as not to include any part having an unduly small radius of curvature. Therefore, a relatively friction free guidance of push-pull cables can be accomplished in actuating the moveable roof panel. Also, the oblique placement of the electric motor enables the electric motor to be placed in a laterally offset position, creating a room for installing an onboard device (30) between the front end of the fixed roof panel and front edge of the roof opening.

Description

TECHNICAL FIELD

The present invention relates to a vehicle roof system including a moveable roof panel and a drive unit for actuating the roof panel between a position to close an opening in a roof of a vehicle and a position to expose the opening.

BACKGROUND OF THE INVENTION

Vehicle roof systems also known as sunroof systems are widely used in passenger vehicles for selectively opening and closing an opening formed in the roof of the vehicle. A typical vehicle roof system comprises a moveable roof panel and a drive unit for actuating the moveable roof panel between a position to close the opening and a position to expose the opening. A pair of guide rails are fixedly secured to the fixed roof panel, and extend along either lateral side of the roof opening, and the moveable roof panel is supported by these guide rails via sliders so as to be slidable in the fore and aft direction. An electric motor is provided centrally on the front edge of the roof opening, and a pair of push-pull cables connected to the corresponding sliders are actuated by the electric motor as required.

The electric motor may be placed either on the front edge or rear edge of the roof opening. If the electric motor is placed on the rear edge of the roof opening, as this part lacks any stiff member, a rear frame is required to be added to the roof structure for supporting the electric motor. It is possible to do away with the rear frame by using highly stiff guide pipes for guiding the push-pull cables, but this also adds to the weight of the vehicle body, and causes some difficulty in the handling of the assembly including the electric motor and guide pipes. Based on such considerations, it is preferable to place the electric motor on the front edge of the roof opening.

It is proposed in co-pending application US20100181805A1 (patent document 1) to mount an electric motor on the front edge of the roof opening, and use guide pipes (drive pipes and idle pipes) made of plastic material which are firmly retained by a front frame via pipe retaining members.

Sometimes, in addition to the electric motor, onboard devices such as room lamps and electric switches are attached to the part of the roof surrounding the roof opening, and such devices are required to be placed so as not to interfere with the electric motor. In particular, a room lamp is provided adjacent to a central part of the front edge of the roof opening. To avoid the interference between the electric motor and room lamp, it was proposed in JP2001-130349A (patent document 2) to provide a sub frame below the electric motor for supporting a map lamp, a room lamp and vanity lamps, and combine the electric motor and sub frame as an assembly that can be installed in the vehicle roof as a single unit.

However, according to the vehicle roof structure disclosed in patent document 2, the room lamp and electric motor are placed one above the other in an overlapping relationship in plan view so that the thickness of the vehicle roof (as measured from the lower surface of the roof lining and the upper surface of the roof panel) inevitably increases. To avoid this problem, it is conceivable to place the room lamp at a relatively forward position, and place the electric motor between the room lamp and the front edge of the roof opening. However, this necessitates the front edge of the roof opening to be placed more rearward than desired. If the roof opening is located too far back in the roof, the viewing angle of the vehicle occupant through the roof opening is so upright that the vehicle occupant's field of view is restricted, and the benefits of the sunroof system are diminished.

BRIEF SUMMARY OF THE INVENTION

In view of such problems of the prior art, a primary object of the present invention is to provide a vehicle roof system that can minimize the thickness of the vehicle roof while ensuring a relatively friction free guidance of push-pull cables for actuating the moveable roof panel.

A second object of the present invention is to provide a vehicle roof system that allows the front edge of the roof opening to be brought highly close to the front end of the roof panel (or the upper edge of the windshield).

A third object of the present invention is to provide a vehicle roof system that can create a space between the front edge of the roof opening and the front end of the fixed roof panel so that an onboard device such as a room lamp may be installed in the space without interfering with the component parts of the vehicle roof system.

According to the present invention, such objects can be accomplished by providing a vehicle roof system for closing and opening a roof opening formed in a fixed roof panel of a vehicle with a moveable roof panel, comprising: a front frame secured to a lower surface of the fixed roof panel and extending laterally along a front edge of the roof opening; a pair of side frames secured to the fixed roof panel and extending longitudinally along a first side edge and a second side edge of the roof opening, respectively; a pair of guide rails fixedly secured to the respective side frames to guide the moveable roof panel for the closing and opening movements thereof; an electric motor attached to the front frame at a position laterally offset toward the second side edge of the roof opening, and having a main body elongated in a direction at an angle with respect to a lateral direction and a vertically extending output shaft fitted with a drive gear; and a pair of push-pull cables meshing with a front and rear side of the drive gear, respectively, and each including a drive section extending from the drive gear laterally along the front frame to the corresponding side frame and an idle section extending from the drive gear laterally along the front frame away from the drive section at least to a corresponding lateral end of the front frame; wherein the drive section of at least one of the push-pull cable includes a bulging section bulging in a forward direction, and the elongated direction of the main body of the electric motor extends substantially in parallel with a sloping inboard side of the bulging section of the one push-pull cable.

As the elongated direction of the electric motor is aligned with a sloping section of the push-pull cable, the push-pull cable can be bulged forward without any restriction so that the push-pull cable can be laid out so as not to include any part having an unduly small radius of curvature. Therefore, a relatively friction free guidance of push-pull cables can be accomplished in actuating the moveable roof panel. Also, the oblique placement of the electric motor enables the electric motor to be placed in a laterally offset position, creating a room for installing an onboard device between the front end of the fixed roof panel and front edge of the roof opening. Therefore, in spite of the presence of such an onboard device, it still is possible to minimize the thickness of the vehicle roof. Furthermore, the front edge of the roof opening can be brought highly close to the front end of the roof panel (or the upper edge of the windshield) so that the vehicle occupant's viewing angle of the front edge of the roof opening can be minimized, and the attractiveness of the vehicle sunroof system can be enhanced.

The bulging section of the one push-pull cable defines a smooth sinusoidal curve with a convex side thereof facing forward so that the frictional resistance to the push-pull cable may be minimized. According to a preferred embodiment of the present invention, the one push-pull cable meshes with the front side of the drive gear so that the electric motor may not be interfered by the idle cable section of the other push-pull cable. In this case, the drive section of the one push-pull cable crosses the idle section of the other push-pull cable.

The drive section of the other push-pull cable may also be provided with a bulging section that crosses the idle section of the other push-pull cable twice so that the drive section of the other push-pull cable may also be guided in a relatively friction-free manner. Typically, the idle section of each push-pull cable extends into the corresponding lateral side of the roof opening along an outboard side of the drive section of the other push-pull cable.

BRIEF DESCRIPTION OF THE DRAWINGS

Now the present invention is described in the following with reference to the appended drawings, in which:

FIG. 1 is a simplified plan view of a vehicle roof system embodying the present invention;

FIG. 2 is a sectional view taken along line II-II of FIG. 1;

FIG. 3 is a sectional view taken along line III-III of FIG. 1;

FIG. 4 is an enlarged fragmentary view of a front part of the vehicle roof system;

FIG. 5 is a sectional view taken along line V-V of FIG. 4;

FIG. 6 is a sectional view taken along line VI-VI of FIG. 4;

FIG. 7 is a sectional view taken along line VII-VII of FIG. 4;

FIG. 8 is a sectional view taken along line VIII-VIII of FIG. 4; and

FIG. 9 is an enlarged view of the layout of the push-pull cables in the area adjacent to the electric motor.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

FIG. 1 is a see-through plan view showing the vehicle roof system embodying the present invention. The illustrated vehicle roof 1 comprises a fixed roof panel 2 accounting for a large part of the vehicle roof 1 and formed with a rectangular opening 2a in a front part thereof, and a sunroof system 3 configured to selectively close and open the roof opening 2a.

A large part of this vehicle roof system is symmetric with respect to the central longitudinal plane of the vehicle body, and only one of two symmetric parts may be discussed in the following description where appropriate as the two parts are essentially identical to each other. In some places, such symmetric parts are denoted with a numeral with a suffix r or l as the case may be to indicate on which side of the vehicle body the parts in question are located. In other places, these parts are collectively denoted with the corresponding numeral without a suffix.

The sunroof system 3 comprises a sunroof frame 10 fixedly secured to the roof panel 2 and surrounding the roof opening 2a, a sunroof panel (moveable roof panel) 4 supported by the sunroof frame 2 so as to be moveable at least in the fore and aft direction (slide movement) and a drive unit 20 for actuating the sunroof panel 4 between a fully open position (rearmost position) and a fully closed position (front-most position). The sunroof system 3 of the illustrated embodiment is additionally configured to raise the rear end of the sunroof panel 4 from the fully closed position (tilt movement).

The sunroof frame 10 includes a pair of side frames 11l and 11r extending along either lateral side of the roof opening 2a, a front frame 12 extending between the front ends of the side frames 11l and 11r and a center frame 13 extending between intermediate parts of the side frames 11l and 11r. The front frame 12 extends along the front edge of the roof opening 2a, and the center frame 13 extends along the rear edge of the roof opening 2a. Therefore, the rear ends of the side frames 11l and 11r extend rearward beyond the rear edge of the roof opening 2a. The front frame 12 is C-shaped in plan view having an open side directed toward the roof opening 2a. In the illustrated embodiment, the side frames 11l and 11r are made of extruded aluminum alloy, and the front and center frames 12 and 13 are made of extruded plastic material.

Additionally referring to FIG. 2, a pair of panel brackets 5l and 5r extending in the fore and aft direction are attached to the lower side of the sunroof panel 4 along either lateral edge thereof. The panel brackets 5l and 5r are fitted with front sliders 6l and 6r and rear sliders 7l and 7r, respectively, by which the sunroof panel 4 is slidably supported by the side frames 11. The rear sliders 7l and 7r are connected to the corresponding panel brackets 5l and 5r via a cam mechanism that controls the sliding movement and tilting movement of the sunroof panel 4 under the actuating force of the drive unit 20.

A front roof rail 8 is attached to the lower side of the roof panel 2 and extends in parallel with the front frame 12 at a small distance ahead thereof. The front roof rail 8 is trough-shaped with a convex side facing upward so as to form a front roof frame 9 having a closed cross section in cooperation with the roof panel 2. The front edge of the front roof frame 9 adjoins the upper edge of a windshield panel 27. The front part of the roof panel 2 and windshield panel 27 slope downward toward the front part of the vehicle so as to jointly define a smooth outer contour. A roof lining 29 overlies the roof panel 2 from below, and defines an opening 29a slightly smaller than the roof opening 2a so that the edge of the opening 29a slightly extends into the roof opening 2a in plan view. A space defined between the roof panel 2 and roof lining 29 receives the main part of the sunroof system 3.

As best illustrated in FIG. 3, each side frame 11 is positioned between the roof panel 2 and roof lining 29, and includes a drain trough section 11a having a U-shaped cross section to drain rainwater out of the sunroof system 3, a cable guide section 11c located on the inboard side of the drain trough section 11a and defining a slot for guiding a push-pull cable 22 connected to the rear slider 7, and a guide rail section 11b located on the inboard side of the cable guide section 11c and defining a slot facing outboard to guide the corresponding front slider 6 and rear slider 7.

Referring to FIG. 2, the side frames 11 are disposed horizontally so that the rainwater received in the drain trough section 11a may be drained either in the forward or rearward direction without overflowing when the vehicle is accelerating or decelerating. Accordingly, the roof lining 29 extends substantially horizontally in the region located behind the front edge of the opening 29a, and is bent slightly downward in the region located ahead of the front edge of the opening 29a so as to conform to the contour of the lower surface of the roof panel 2. A pair of sun visor units 31r and 31l for the vehicle operator and the passenger are mounted on the lower side of the part of the roof lining 29 located ahead of the front edge of the opening 29a as shown in FIG. 4.

Referring to FIG. 1, the drive unit 20 includes an electric motor 24 attached to the lower surface of the front frame 12 in an rightwardly offset position and internally incorporated with a gear reduction unit (not shown in the drawings), a drive gear 23 attached to an output end of the electric motor 24, and a pair of push-pull cables 22r and 22l each having one end connected to the corresponding rear slider 7, and defining a driven rack gear 21 formed by spirally winding a steel wire around a steel core wire and meshing with the drive gear 23. The electric motor 24 includes a main body elongated in the direction of a rotor shaft thereof (not shown in the drawings) and at an angle with respect to the lateral direction of the vehicle body. The rear and inboard end of the main body of the electric motor 24 is provided with a gear reduction mechanism which transmits the rotation of the rotor shaft of the electric motor 24 to the output shaft that supports the drive gear 23 and extends vertically.

A map lamp unit 30 is attached to the front frame 12 via a bracket not shown in the drawing, and fitted into an opening 29b formed in the roof lining 29 at a laterally central part therefore (FIG. 7) so that the map lamp unit 30 is received in a space defined between the fixed roof panel 1 and roof lining 29 but is exposed to the passenger compartment. Therefore, the map lamp unit 30 is located centrally adjacent to the front edge of the roof opening 2a while the electric motor 24 is placed laterally offset from the map lamp unit 30 so as not to interfere with each other. In particular, the electric motor 24 does not substantially overlap with the map lamp unit 30 when viewed from the front but substantially overlaps with the map lamp unit 30 when viewed from the side. See FIGS. 7 and 8.

Each push-pull cable 22 includes a drive cable section 22a extending from the drive gear 23 to the corresponding rear slider 7 to transmit the drive force of the electric motor 24 to the rear slider 7, and an idle cable section 22b extending from the drive gear 23 in the opposite direction from the drive cable section 22a without being subjected to any loading. The drive cable section 22a is linearly guided by the cable guide section 11c of the side frame 11, and guided by a drive pipe 25 secured to the front frame 12 between the drive gear 23 and the front end of the cable guide section 11c along a curved path. The drive pipe 25 may be conveniently made of plastic material that allows the drive pipe 25 to be curved as desired without any difficulty. The idle cable section 22b is likewise guided by an idle pipe 26 secured to the front frame 12 along a partly curved path (FIG. 5). As the electric motor 24 is offset in the rightward direction, a part of the idle pipe 261 (the part located to the right of the drive gear 23 in FIG. 1) for the left push-pull cable 22l extends rearward from the right end of the front frame 12, and the remaining part of the idle pipe 261 extends along the right side frame 11r (FIG. 2).

These guide pipes (drive pipes 25 and idle pipes 26) not only protect the push-pull cables 22 from moisture, dust and other foreign matters, but also control the deflection of the push-pull cable 22 as being pushed and pulled by the drive gear 23 so that the rear sliders 7 may be displaced in a prescribed relationship to the rotational angle of the drive gear 23. The two push-pull cables 22l and 22r oppose each other in a mutually parallel relationship (both extending in the lateral direction) at the drive gear 23, and are urged toward each other by spring members so that the rotational movement of the drive gear 23 may be transmitted to the rear sliders 7l and 7r in a properly synchronized relationship. In the illustrated embodiment, the push-pull cable 22 connected to the right lateral end of the sunroof panel 4 or the right rear slider 7r extends along the front side of the drive gear 23, and the push-pull cable 22 connected to the left lateral end of the sunroof panel 4 or the left rear slider 7l extends along the rear side of the drive gear 23.

The sunroof panel 4 defines an outer contour continuously and smoothly connected to the roof panel 2 in the fully closed position thereof. When the electric motor 24 further pulls the push-pull cables 22 via the drive gear 23 from the fully closed position of the sunroof panel 4, the rear end of the sunroof panel 4 is raised to place the sunroof panel 4 in a tilted up position by means of the cam mechanism incorporated in the rear sliders 7. When the push-pull cables 22 are pushed from this state, the sunroof panel 4 is tilted down, and returns to the fully closed position. When the push-pull cables 22 are pushed from the fully closed position, the rear sliders 7 are displaced rearward, and this causes the sunroof panel 4 to be lowered below the roof panel 2 and to be moved rearward at the same time. When the sunroof panel 4 is displaced to the rearmost position thereof, the opening 2a is fully opened. When the push-pull cables 22 are pulled from this state, the sunroof panel 4 eventually closes the roof opening 2a reversing the aforementioned process.

The structure of the vehicle roof around the front frame 12 is now described in the following with reference to FIGS. 4 to 8. FIG. 4 shows the part of the roof 1 surrounding the front frame 12 in plan view with the roof panel 2 and sunroof panel 4 indicated by imaginary lines. Referring to FIGS. 4 and 5, the front frame 12 includes front planar part 12a extending under and in parallel with the roof panel 2 (thereby slightly sloping downward toward the front), a rear planar part 12b extending horizontally behind the front planar part 12a at a lower elevation, and a groove part 12c located between the front planar part 12a and rear planar part 12b and depressed more than these two parts. The groove part 12c includes a front wall 12d, a rear wall 12e and a bottom wall 12f, and the bottom wall 12f is lower than the front planar part 12a or the rear planar part 12b.

The front planar part 12a is provided with a drive pipe retaining groove 16l (16r) for retaining the drive pipe 25 and an idle pipe retaining groove 17r (17l) for retaining the idle pipe 26, both opening out upward. A side wall of each pipe retaining groove 16 and 17 is provided with a plurality of clamps 18 including resilient tabs 18a resiliently clamping the drive and idle pipes 25 and 26 against the opposing side wall. The free end of each resilient tab 18a is formed with a barb that facilitates the insertion of the pipe 25, 26 into the groove 16, 17, but opposes the dislodging of the pipe from the groove. Thereby, the drive and idle pipes 25 and 26 can be easily installed and removed as required, and are additionally prevented from deflecting once installed even when the drive and idle pipes 25 and 26 are made of relatively flexible plastic material and the push-pull cables 22 received therein are subjected to tensile and compressive forces.

As shown in FIGS. 4 and 6, the front planar part 12a is formed with a through hole 15 at a part laterally offset to the right from the center for passing the drive gear 23 from below, and the two pipe retaining grooves extend along the front and rear sides of the through hole 15 both in the lateral direction (in a mutually parallel relationship). In particular, the drive pipe retaining groove 16l and the idle pipe retaining groove 17l for the left push-pull cable 22l extends along the rear side of the drive gear 23, and the drive pipe retaining groove 16l r and the idle pipe retaining groove 17r for the right push-pull cable 22r extend along the front side of the drive gear 23.

As best shown in FIG. 4, the idle cable sections of the push-pull cables 22 extend along the corresponding side frames 11 on outboard sides of the adjacent drive cable sections of the other push-pull cables 22. Therefore, it is necessary that the two push-pull cables 22 cross each other at least at one location. In that case, the left push-pull cable 22l that meshes with the rear side of the drive gear 23 is required to be more sharply bent than the right push-pull cable 22r that meshes with the front side of the drive gear 23 as the push-pull cable extends from the corresponding lateral end of the front frame 12 to the corresponding side frame 11.

According to the present invention, in addition to that the idle cable section of the left push-pull cable 22l crosses the drive cable section of the right push-pull cable 22r at one location P1, the drive cable section of the left push-pull cable 22l includes a bulging section bulging forward by crossing the idle cable section of the right push-pull cable 22r at two locations P2 and P3. Thereby, the drive cable section of the left push-pull cable 22l which is otherwise required to be most sharply bent is allowed to curve more gradually by forming a bulging section that extend forward beyond the idle cable section of the right push-pull cable 22r.

Referring to FIGS. 4 and 9, the electric motor 24 is provided with a base plate 24a fixedly attached to the lower surface of the front planar part 12a of the front frame 12, a gear reduction unit attached to the lower surface of the base plate 24a and a motor main body 24b received in a casing common to the gear reduction unit. The base plate 24a is rectangular in shape, and has a small thickness (vertical dimension). The base plate 24 is disposed so that the four sides thereof are in parallel with the lateral and longitudinal direction of the vehicle body. The motor main body 24b is approximately cylindrical in shape, and is rectangular in plan view. The axial line of the motor main body 24b is at an angle with the lateral direction of the vehicle body.

The drive section of each push-pull cable is subjected to a greater loading than the idle section, and is therefore required to be free from a section of a small curvature of radius. Therefore, the drive section of the right push-pull cable 22r is provided with a bulging section that bulges forward as it extends from the section in parallel with the front frame 12 and a section in parallel with the side frame 11. As shown in FIG. 9, the drive section of the right push-pull cable 22r includes a first linear section S0 extending laterally (rightward) from the drive gear 23, a first curved section S2 (having a radius of curvature of R1) connected to the right end of the first linear section S0 and convex toward the rear, a second curved section S3 (having a radius of curvature of R2) connected to the right end of the first curved section S2 and convex toward the front, and a second linear section S4 extending from the right end of the second curved section S3 in the longitudinal direction. These sections are connected in a smooth manner (without any discontinuity in the inclination or sloping angle). Thereby, the radius of curvature of the drive section of the right push-pull cable 22r is maintained above a prescribed limit over the entire length thereof, and a relatively friction-free guidance of the push-pull cable is enabled.

In particular, as the motor main body 24b is placed adjacent to and in parallel to the inboard-side sloping section of the push-pull cable or the inboard side of the bulging section (which may include adjoining parts of the first and second curved section S2 and S3), the electric motor 24 can be placed in a compact manner without interfering with the bulging section of the push-pull cable that bulges forward.

The drive pipe retaining grooves 16l and 16r are provided at a substantially same elevation as the front planar part 12a over the entire lengths thereof (FIG. 5). On the other hand, the idle pipe retaining grooves 17l and 17r are at the substantial same elevation as the front planar part 12a only in the part adjacent to the through hole 15, and slope progressively downward toward the both lateral sides of the vehicle body so that the idle pipe retaining grooves 17l and 17r are enabled cross under the drive pipe retaining grooves 16l and 16r without interfering with them (FIG. 4).

The front part of the front frame 12 of the front planar part 12 is provided with a plurality (four, in the illustrated embodiment) of mounting bosses 14a to 14d projecting upward and arranged laterally at an approximately regular interval. Each mounting boss is formed with a through hole for receiving a fastener such as a screw or clip that secures the front frame 12 to the roof panel 2 (via a bracket not shown in the drawings). As the front frame 12 is attached to the roof panel 2 at the four locations, the stiffness of the front frame 12 is ensured, and is prevented from excessively deforming or breaking when subjected to the force transmitted from the push-pull cables 22 even though the front frame 12 is made of light-weight plastic material.

The groove part 12c of the front frame 12 is provided with a drain outlet 12g on each lateral end thereof for expelling the rainwater received in the groove part 12c to the drain system of the sunroof system 3 not shown in the drawings. The bottom wall of the drain outlet 12g is substantially at the same elevation as that of the groove part 12c, and the height of the side walls of each drain outlet 12g is determined so as not interfere with the idle pipe 26 extending above the drain outlet 12g.

As shown in FIGS. 4, 7 and 8, the map lamp unit 30 is provided centrally on the front edge of the roof opening 2a, and is received in the opening 29b formed in the roof lining 29 so as to face the interior of the passenger compartment 28. The map lamp unit 30 is fixedly secured to the roof panel 2 via a bracket not shown in the drawings. The map lamp unit 30 may include map lamps for illuminating localized parts of the front seats, a room lamp for illuminating the entire passenger compartment 28 and a switch panel for turning on and off these lamps and controlling the sunroof system 3, as a single assembly supported by a common frame. The main part of the map lamp unit 30 is received in the space between the roof lining 29 and roof panel 2, and the lower surface of the map lamp unit 30 is substantially flush with the surface of the remaining part of the roof lining 29.

The map lamp unit 30 is located between the front wall 12d of the front frame 12 and the rear wall of the front roof frame 9 without interfering with them. In particular, in side view, the map lamp unit 30 is located ahead of the front wall 12d of the front frame 12, and the rear end of the map lamp unit 30 may be located under the front planar part 12a. Because the electric motor 24 is located so as not to overlap with the map lamp unit 30 in front view, the map lamp unit 30 may overlap with the electric motor 24 in side view without interfering with each other. By positioning the map lamp unit 30 so as to be partly located under the front planar part 12a of the front frame 12 and overlap with the electric motor 24 in side view, the distance between the front frame 12 and front roof frame 9, in particular the distance between the front edge of the roof 1 to the front edge of the roof opening 2a of the roof panel 2 can be minimized so that the vehicle occupant's viewing angle of the front edge of the roof opening 2a can be minimized. The electric motor 24 is also located between the rear wall of the front roof frame 9 and the front wall 12d of the front frame 12, and about a rear half of the electric motor 24 is located under the front planar part 12a of the front frame 12. As the electric motor 24 and map lamp unit 30 do not overlap each other in plan view (FIG. 4), the thickness of the roof 1 or the distance between the lower surface of the roof lining 29 and upper surface of the roof panel 2 can be minimized.

Each sun visor 31 is located on the side (or the lower side) of the roof lining 29 facing the passenger compartment 28, and is pivotable around a pivot shaft 31X extending laterally between a stowed position closely overlying the lower surface of the roof lining 29 as indicated by the solid lines in FIG. 6, and a deployed position extending vertically downward from the pivot shaft 31X as indicated by the imaginary lines in FIG. 6 to shield the sunlight from the front from the view of the vehicle occupant.

In particular, because the electric motor 24 is placed in a laterally offset position, one of the sun visors 31 is located under the electric motor 24 in the stowed position thereof in an overlying relationship in plan view, the sun visor 31 can shield or muffle the acoustic noises generated from the electric motor 24. The roof lining 29 is formed with a pair of recesses 29c for at least partly receiving the corresponding sun visors 31 therein. The rear end of each recess 29c is located ahead of the front wall 12d of the groove part 12c of the front frame 12 so that the recesses 29c can be formed by making use of the space available above the upper surface of the corresponding parts of the roof lining 29, and the protrusion of the sun visors 31 from the lower surface of the roof lining 29 can be minimized.

Referring to FIG. 4, the leftmost mounting boss 14a is located between the drive pipe retaining groove 16l and idle pipe retaining groove 17r on the front planar part 12a of the front frame 12, and the second mounting boss 14b from the left is located adjacent to the left end of the map lamp unit 30. The third mounting boss 14c from the left is located adjacent to the right end of the map lamp unit 30 or between the map lamp unit 30 and electric motor 24, and the rightmost mounting boss 14d is located adjacent to the right end of the electric motor 24 and between the drive pipe retaining groove 16r and idle pipe retaining groove 17l on the front planar part 12a of the front frame 12. Therefore, two of the attaching points 14a and 14d are located between the two push-pull cables on either side of the middle crossing location P2. In the illustrated embodiment, the four mounting bosses 14a to 14d are arranged at an equal interval, but may also be located at irregular intervals.

As the third mounting boss 14c is located between the map lamp unit 30 and electric motor 24, the spacings between the adjacent mounting bosses 14a to 14d can be at least relatively uniform without causing any one of the spacings to be excessively great so that the front frame 12 is free from any low-stiffness region even though the front frame 12 is made of plastic material or other relatively flexible material. As the two of the mounting bosses 14c and 14d are provided on either side of the electric motor 24 in close proximity, the stiffness of the part of the front frame 12 adjacent to the electric motor 24 is particularly increased so that the front frame 12 is prevented from excessively deforming or breaking by the force transmitted from the electric motor 24 when actuating the push-pull cables 22 even though the front frame 12 is made of plastic material or other relatively flexible material.

Although the present invention has been described in terms of a preferred embodiment thereof, it is obvious to a person skilled in the art that various alterations and modifications are possible without departing from the scope of the present invention which is set forth in the appended claims. For instance, the present invention is equally applicable to a sunroof system which is capable of only the slide movement, and also to a sunshade system which opens and closes a moveable roof panel in the form of a sunshade configured to open and close an opening provided in the roof lining. For actuating the sunroof or sunshade panel, rack belts and other cables capable of transmitting the actuating force can also be used, instead of the push-pull cables of the illustrated embodiment, without departing from the spirit of the present invention.

The contents of the original Japanese patent application on which the Paris Convention priority claim is made for the present application as well as the contents of the prior art references mentioned in this application are incorporated in this application by reference.

Claims

1. A vehicle roof system for closing and opening a roof opening formed in a fixed roof panel of a vehicle with a moveable roof panel, comprising: a front frame secured to a lower surface of the fixed roof panel and extending laterally along a front edge of the roof opening;a pair of side frames secured to the fixed roof panel and extending longitudinally along a first side edge and a second side edge of the roof opening, respectively;a pair of guide rails fixedly secured to the respective side frames to guide the moveable roof panel for the closing and opening movements thereof;an electric motor attached to the front frame at a position laterally offset toward the second side edge of the roof opening, and having a main body elongated in a direction at an angle with respect to a lateral direction and a vertically extending output shaft fitted with a drive gear; anda pair of push-pull cables meshing with a front and rear side of the drive gear, respectively, and each including a drive section extending from the drive gear laterally along the front frame to the corresponding side frame and an idle section extending from the drive gear laterally along the front frame away from the drive section at least to a corresponding lateral end of the front frame;wherein the drive section of at least one of the push-pull cable includes a bulging section bulging in a forward direction, and the elongated direction of the main body of the electric motor extends substantially in parallel with a sloping inboard side of the bulging section of the one push-pull cable.

2. The vehicle roof system according to claim 1, wherein the bulging section of the one push-pull cable defines a smooth sinusoidal curve with a convex side thereof facing forward.

3. The vehicle roof system according to claim 1, wherein the one push-pull cable meshes with the front side of the drive gear.

4. The vehicle roof system according to claim 3, wherein the drive section of the other push-pull cable is also provided with a bulging section that crosses the idle section of the other push-pull cable twice.

5. The vehicle roof system according to claim 4, wherein the drive section of the one push-pull cable crosses the idle section of the other push-pull cable.

6. The vehicle roof system according to claim 3, wherein the idle section of each push-pull cable extends into the corresponding lateral side of the roof opening along an outboard side of the drive section of the other push-pull cable.